Apparatus and method for positioning a cassette pod onto a loadport by an overhead hoist transport system

1. An apparatus for positioning a cassette pod by an overhead hoist transport (OHT) system comprising: four sensor plates positioned on a top surface of a loadport on a process machine forming a planar area surrounded by said plates, said planar area being smaller than a bottom surface area of said cassette pod, each of said sensor plates being positioned at an angle inclining outwardly with a back surface of the plate supported by a connecting rod and a compressible spring such that each of said sensor plates being capable of moving outwardly away from said planar area when pushed by a cassette pod, each of said connecting rods or said sensor plates being equipped with a vibration sensor for sensing any movement of a sensor plate; a concave mirror mounted on a bottom surface of said cassette pod having a reflective surface facing downwardly; a light source and a photosensor positioned at a center of said planar area on said loadport for projecting a light beam upwardly toward said concave mirror when activated by one of said vibration sensors mounted on one of said four sensor plates or said connecting rods to be reflected and received by said photo sensor; and a process controller for receiving a signal from said photosensor indicating a position of said cassette pod and for sending a signal to said overhead hoist transport system so that the position of said OHT system is calibrated accordingly.

2. An apparatus for positioning a cassette pod by an overhead hoist transport system according to claim 1 , wherein each of said sensor plates being positioned at an angle between about 30 and about 75 as measured from a top surface of said loadport where said compressible spring is supported.

3. An apparatus for positioning a cassette pod by an overhead hoist transport system according to claim 1 , wherein each of said sensor plates being positioned at an angle between about 30 and about 60 as measured from a top surface of said loadport where said compressible spring is supported.

4. An apparatus for positioning a cassette pod by an overhead hoist transport system according to claim 1 , wherein a lower edge of each of said four sensor plates being provided with a roller means for engaging a recessed track in said top surface of said loadport.

5. An apparatus for positioning a cassette pod by an overhead hoist transport system according to claim 1 , wherein said compressible spring being positioned parallel to said top surface of the loadport for engaging a lower end of said connecting rod.

6. An apparatus for positioning a cassette pod by an overhead hoist transport system according to claim 1 , wherein said compressible spring being positioned parallel to said top surface of the loadport for restoring the position of a sensor plate after the plate is pushed outwardly by a cassette pod.

7. An apparatus for positioning a cassette pod by an overhead hoist transport system according to claim 1 , wherein said connecting rod pivotally engages and supports a back surface of the sensor plate.

8. An apparatus for positioning a cassette pod by an overhead hoist transport system according to claim 1 , wherein said light source and said photosensor being provided in an electro-optical assembly.

9. An apparatus for positioning a cassette pod by an overhead hoist transport system according to claim 1 , wherein said sensor plate being fabricated of a lightweight, rigid material such as aluminum or plastic.

10. An apparatus for positioning a cassette pod by an overhead hoist transport system according to claim 1 , wherein said sensor plate being fabricated in a dimension of about 10 cm 10 cm.

11. A method for positioning a cassette pod by an overhead hoist transport (OHT) system comprising the steps of: positioning four sensor plates on a top surface of a loadport on a process machine forming a planar area surrounded by said plates, said planar area being smaller than a bottom surface area of said cassette pod, each of said sensor plates being positioned at an angle inclining outwardly with a back surface of the plate supported by a connecting rod and a compressible spring such that each of said sensor plates being capable of moving outwardly away from said planar area when pushed by a cassette pod, each of said connecting rods or said sensor plates being equipped with a vibration sensor for sensing any movement of a sensor plate; mounting a concave mirror on a bottom surface of said cassette pod having a reflective surface facing downwardly; mounting a light source and a photosensor at a center of said planar area on said loadport; projecting a light beam upwardly to said concave mirror when said light source is activated by one of said vibration sensors such that the beam is reflected and received by said photo sensor; sending a first signal to a process controller from said photosensor indicating a position of said cassette pod and calculating a deviation; and sending a second signal from said process controller to said overhead hoist transport system to calibrate the movement of said OHT system based on said deviation.

12. A method for positioning a cassette pod by an overhead hoist transport system according to claim 11 further comprising the step of positioning each of said sensor plates at an angle between about 30 and about 75 as measured from a top surface of said loadport where said compressible spring is supported.

13. A method for positioning a cassette pod by an overhead hoist transport system according to claim 11 further comprising the step of positioning each of said sensor plates at an angle between about 30 and about 60 as measured from a top surface of said loadport where said compressible spring is supported.

14. A method for positioning a cassette pod by an overhead hoist transport system according to claim 11 further comprising the step of: mounting a roller means on a lower edge of each of said four sensor plates; and engaging said roller means in a recessed track in said top surface of said loadport.

15. A method for positioning a cassette pod by an overhead hoist transport system according to claim 11 further comprising the step of positioning said compressible spring parallel to said top surface of the loadport and engaging a lower end of said connecting rod.

16. A method for positioning a cassette pod by an overhead hoist transport system according to claim 15 further comprising the step of restoring the position of a sensor plate after the plate is pushed outwardly by a cassette pod.

17. A method for positioning a cassette pod by an overhead hoist transport system according to claim 11 further comprising the step of pivotally engaging and supporting a back surface of the sensor plate by said connecting rod.

18. A method for positioning a cassette pod by an overhead hoist transport system according to claim 11 further comprising the step of providing an electro-optical assembly that contains a light source and a photosensor.

19. A method for positioning a cassette pod by an overhead hoist transport system according to claim 11 further comprising the step of fabricating said sensor plate of a lightweight, rigid material such as aluminum or plastic.

20. A method for positioning a cassette pod by an overhead hoist transport system according to claim 11 further comprising the step of fabricating said sensor plate in a dimension of about 10 cm 10 cm.